KR20220150138A - Carbon sheet and porous catalyst comprising the same - Google Patents

Abstract

Provided are a carbon sheet and a porous catalyst comprising the same. The carbon sheet is the carbon sheet having micro pores and containing nitrogen (N). The carbon sheet is formed by a method including the steps of: forming a precursor solution containing a carbon precursor containing nitrogen (N); forming a template-carbon composite by providing a template to the precursor solution and drying the precursor solution; forming a first carbon sheet by performing a first heat treatment on the template-carbon composite; and forming a second carbon sheet having micropores by performing a second heat treatment on the first carbon sheet. The porous catalyst is the porous catalyst having micropores, containing nitrogen (N), and supporting a metal. The porous catalyst is formed by a method including the steps of: forming a precursor solution containing a carbon precursor containing nitrogen (N) and a metal precursor; forming a template-metal-carbon composite by providing a template to the precursor solution and drying the precursor solution; forming a first carbon sheet supporting the metal by performing a first heat treatment on the template-metal-carbon composite; and forming a second carbon sheet having micropores and supporting the metal by performing a second heat treatment on the first carbon sheet. According to the present invention, the carbon sheet and the porous catalyst can be easily formed in an environmentally friendly manner.

Description

Carbon sheet and porous catalyst comprising the same

The present invention relates to a carbon sheet and a porous catalyst comprising the same.

One of the most well-known two-dimensional carbon materials is graphene. Graphene is manufactured by exfoliation of graphite or chemical vapor deposition (CVD), but there is a problem in that the manufacturing process is complicated and dangerous chemicals are used.

The present invention provides a novel carbon sheet.

The present invention provides a method for forming the carbon sheet.

The present invention provides a porous catalyst having excellent performance.

The present invention provides a method for forming the porous catalyst.

Other objects of the present invention will become apparent from the following detailed description and accompanying drawings.

The carbon sheet according to the embodiments of the present invention is a carbon sheet having micropores and containing nitrogen (N), the step of forming a precursor solution containing a carbon precursor containing nitrogen, and providing a template to the precursor solution and then drying the precursor solution to form a template-carbon composite, performing a first heat treatment on the template-carbon composite to form a first carbon sheet, and a second heat treatment on the first carbon sheet It is formed by a method comprising the step of performing a second carbon sheet having micropores.

The carbon precursor may include dopamine.

The template may include salt (NaCl). The method may further include removing the template after the first heat treatment, and the template may be removed by dissolving with water.

The first heat treatment may be performed under an inert gas at a first temperature, and the second heat treatment may be performed at a second temperature higher than the first temperature under NH ₃ gas or CO ₂ gas.

The first carbon sheet and the second carbon sheet may have a two-dimensional structure.

A method of forming a carbon sheet according to embodiments of the present invention includes forming a precursor solution including a carbon precursor including nitrogen, providing a template to the precursor solution, and then drying the precursor solution to form a template-carbon composite forming a, performing a first heat treatment on the template-carbon composite to form a first carbon sheet, and performing a second heat treatment on the first carbon sheet to obtain a second carbon sheet having micropores forming a step.

The carbon precursor may include dopamine.

The template may include salt. The method of forming the carbon sheet may further include removing the template after the first heat treatment, and the template may be removed by dissolving it with water.

The first heat treatment may be performed under an inert gas at a first temperature, and the second heat treatment may be performed at a second temperature higher than the first temperature under NH ₃ gas or CO ₂ gas.

The first carbon sheet and the second carbon sheet may have a two-dimensional structure.

The porous catalyst according to embodiments of the present invention is a porous catalyst having micropores and containing nitrogen (N) and supporting a metal, the step of forming a precursor solution including a carbon precursor and a metal precursor containing nitrogen; forming a template-metal-carbon composite by providing a template to the precursor solution and then drying the precursor solution; performing a first heat treatment on the template-metal-carbon composite to support the metal first carbon sheet It is formed by a method comprising the steps of forming a, and performing a second heat treatment on the first carbon sheet to form a second carbon sheet having micropores and supporting the metal.

The carbon precursor may include dopamine.

The metal precursor may include a transition metal. The porous catalyst may include an M-N-C structure (M represents a transition metal).

The template may include salt (NaCl). The method may further include removing the template after the first heat treatment, and the template may be removed by dissolving with water.

The first heat treatment may be performed under an inert gas at a first temperature, and the second heat treatment may be performed at a second temperature higher than the first temperature under NH ₃ gas or CO ₂ gas.

The first carbon sheet and the second carbon sheet may have a two-dimensional structure.

According to embodiments of the present invention, a new carbon sheet and a porous catalyst including the same are provided. The carbon sheet may have excellent electrochemical activity in a two-dimensional structure including nitrogen and having micropores. For example, the carbon sheet may have excellent oxygen reduction reaction activity and durability. An electrocatalyst with improved performance may be implemented by applying the carbon sheet. In addition, since the carbon sheet has high electrical conductivity and durability, it can be used as a material for a negative electrode and a positive electrode of a battery.

The porous catalyst may have excellent performance. For example, the porous catalyst may have excellent oxygen reduction reaction activity and durability.

The carbon sheet and the porous catalyst can be easily formed in an environmentally friendly manner, and the synthesis scale can be easily expanded for mass production.

1 shows a TEM image of the NCS.
2 shows an AFM image of the NCS.
FIG. 3 shows the profile taken along lines (i), (ii), and (iii) of FIG. 2 .
4 shows a TEM image of NCS(m).
5 shows a TEM image of NCB (m).
6 shows N ₂ adsorption and desorption isotherms of NCS, NCS (m), NCB, and NCB (m).
7 shows the BET surface area and micropore surface area of NCS(m) and NCB(m).
8 shows N 1s XPS spectra of NCS, NCS(m), NCB, and NCB(m).
9 shows the N functional group content of NCS, NCS(m), NCB, and NCB(m).
10 shows the oxygen reduction reaction polarities of NCS, NCS(m), NCB, and NCB(m).
11 shows the kinetic current densities of NCS, NCS(m), NCB, and NCB(m).
12 and 13 show the results of EIS analysis of NCS (m) and NCB (m).
14 shows a TEM image of Fe-NCS(m).
15 shows an AC-STEM image of Fe-NCS(m).
16 shows the CCWT analysis results of Fe-NCS(m), Fe-Phen, Fe3O4, and Fe EXAFS of Fe metal foil.
17 shows the oxygen reduction reaction polarity curves of NCS(m), Fe-NCS(m), and Pt/C.
18 shows the durability test results of Fe-NCS(m) and Pt/C.
19 shows the half-wave potentials of Fe-NCS(m) and Pt/C before and after 20,000 cycles.

Hereinafter, the present invention will be described in detail through examples. Objects, features, and advantages of the present invention will be readily understood through the following examples. The present invention is not limited to the embodiments described herein, and may be embodied in other forms. The embodiments introduced herein are provided so that the disclosed content can be thorough and complete, and the spirit of the present invention can be sufficiently conveyed to those of ordinary skill in the art to which the present invention pertains. Therefore, the present invention should not be limited by the following examples.

Although terms such as first, second, etc. are used herein to describe various elements, the elements should not be limited by these terms. These terms are only used to distinguish the elements from each other. Also, when an element is referred to as being above another element, it means that it may be formed directly on the other element or that a third element may be interposed therebetween.

As used herein, the term NCS indicates a carbon sheet containing N without micropores, and NCS(m) indicates a carbon sheet containing N while having micropores. NCB indicates a carbon ball containing N without having micropores, and NCB(m) indicates a carbon ball containing N while having micropores. In addition, M-NCS(m) represents NCS(m) on which the metal (M) was supported. For example, Fe-NCS(m) represents NCS(m) on which Fe is supported. The carbon sheet may include a carbon nano sheet.

The carbon sheet according to the embodiments of the present invention is a carbon sheet having micropores and containing nitrogen (N), the step of forming a precursor solution containing a carbon precursor containing nitrogen, and providing a template to the precursor solution and then drying the precursor solution to form a template-carbon composite, performing a first heat treatment on the template-carbon composite to form a first carbon sheet, and a second heat treatment on the first carbon sheet It is formed by a method comprising the step of performing a second carbon sheet having micropores.

A method of forming a carbon sheet according to embodiments of the present invention includes forming a precursor solution including a carbon precursor including nitrogen, providing a template to the precursor solution, and then drying the precursor solution to form a template-carbon composite forming a, performing a first heat treatment on the template-carbon composite to form a first carbon sheet, and performing a second heat treatment on the first carbon sheet to obtain a second carbon sheet having micropores forming a step.

The carbon precursor may include dopamine.

The template may include salt (NaCl). The method may further include removing the template after the first heat treatment, and the template may be removed by dissolving with water. The removed salt can be recycled by evaporating the water.

The first heat treatment may be performed under an inert gas at a first temperature, and the second heat treatment may be performed at a second temperature higher than the first temperature under NH ₃ gas or CO ₂ gas.

The first carbon sheet and the second carbon sheet may have a two-dimensional structure.

The porous catalyst according to embodiments of the present invention is a porous catalyst having micropores and containing nitrogen (N) and supporting a metal, the step of forming a precursor solution including a carbon precursor and a metal precursor containing nitrogen; forming a template-metal-carbon composite by providing a template to the precursor solution and then drying the precursor solution; performing a first heat treatment on the template-metal-carbon composite to support the metal first carbon sheet It is formed by a method comprising the steps of forming a, and performing a second heat treatment on the first carbon sheet to form a second carbon sheet having micropores and supporting the metal.

A method of forming a porous catalyst according to embodiments of the present invention includes forming a precursor solution including a carbon precursor and a metal precursor including nitrogen, providing a template to the precursor solution, and then drying the precursor solution to provide a template - Forming a metal-carbon composite, performing a first heat treatment on the template-metal-carbon composite to form a first carbon sheet supporting the metal, and a second heat treatment on the first carbon sheet and forming a second carbon sheet having micropores and supporting the metal.

The carbon precursor may include dopamine.

The metal precursor may include a transition metal. The porous catalyst may include an M-N-C structure (M represents a transition metal).

The template may include salt (NaCl). The method may further include removing the template after the first heat treatment, and the template may be removed by dissolving with water. The removed salt can be recycled by evaporating the water.

The first heat treatment may be performed under an inert gas at a first temperature, and the second heat treatment may be performed at a second temperature higher than the first temperature under NH ₃ gas or CO ₂ gas.

The first carbon sheet and the second carbon sheet may have a two-dimensional structure.

[Example]

[Example of formation of NCS]

Dissolve 1 g of dopamine hydrochloride in 100 mL of tris-HCl buffer (pH 8.5). This solution is added to 500 g of salt (NaCl) and stirred continuously so that the solution is sufficiently wetted on the surface of the salt. The salt functions as a template for forming a two-dimensional carbon sheet. When the solution is sufficiently applied to the salt, it is dried at room temperature for one day and then sufficiently dried in a vacuum oven at 80°C. Thereby, polymerization of dopamine hydrochloride is carried out, and a salt-dopamine complex is formed.

The salt-dopamine complex is heat-treated in a tube furnace at 700° C. (ramp rate = 5° C./min) for 2 hours under an inert gas (Ar with a flow rate of 100 sccm). After the heat treatment, when the salt is dissolved and removed with deionized water, a two-dimensional structure of NCS can be obtained.

[Example of formation of NCS(m)]

The NCS(m) is formed by performing an activation heat treatment on the NCS. The NCS is placed in a tube furnace and heated to 900°C (ramp rate = 5°C/min) under inert gas (100 sccm of Ar). When the temperature reaches 900° C., the inert gas is converted into NH ₃ gas or CO ₂ gas at a flow rate of 60 sccm. After heat treatment for 15 minutes under NH ₃ gas or CO ₂ gas for the NCS, when cooled to room temperature under an inert gas (100 sccm of Ar), NCS (m) having a two-dimensional structure having micropores can be obtained.

[Formation example of Fe-NCS(m)]

When 1 g of dopamine hydrochloride is dissolved in 100 mL of tris-HCl buffer (pH 8.5), 10 mg of FeCl ₃ .6H ₂ O is added. This solution is added to 500 g of salt (NaCl) and stirred continuously so that the solution is sufficiently wetted on the surface of the salt. The salt functions as a template for forming a two-dimensional carbon sheet. When the solution is sufficiently applied to the salt, it is dried at room temperature for one day and then sufficiently dried in a vacuum oven at 80°C. Thereby, polymerization of dopamine hydrochloride is carried out, and a salt-Fe-dopamine complex is formed.

The salt-Fe-dopamine complex was heat-treated in a tube furnace at 700° C. (ramp rate = 5° C./min) for 2 hours under an inert gas (Ar with a flow rate of 100 sccm). After the heat treatment, when the salt is dissolved in deionized water and removed, Fe-NCS having a two-dimensional structure can be obtained.

Fe-NCS(m) is formed by performing an activation heat treatment on Fe-NCS. The Fe-NCS is placed in a tube furnace and heated to 900 °C (ramp rate = 5 °C/min) under inert gas (100 sccm of Ar). When the temperature reaches 900° C., the inert gas is converted into NH ₃ gas or CO ₂ gas at a flow rate of 60 sccm. After performing heat treatment for 15 minutes under NH ₃ gas or CO ₂ gas, when cooled to room temperature under an inert gas (100 sccm of Ar), Fe-NCS (m) having a two-dimensional structure having micropores can be obtained.

[Example of formation of Co-NCS(m)]

Co-NCS(m) is formed in the same manner except for using CoCl ₂ .6H ₂ O instead of FeCl ₃ .6H ₂ O in the formation example of Fe-NCS(m).

[Formation example of Ni-NCS(m)]

Ni-NCS(m) is formed in the same manner except for using NiCl ₂ .6H ₂ O instead of FeCl ₃ .6H ₂ O in the formation example of Fe-NCS(m).

[Example of formation of Mn-NCS(m)]

Mn-NCS(m) is formed in the same manner except for using MnCl ₂ .6H ₂ O instead of FeCl ₃ .6H ₂ O in the formation example of Fe-NCS(m).

[Comparative example]

[Example of formation of NCB]

Aqueous ammonia solution (NH ₄ OH, 1 mL, 28-30 %) is mixed with ethanol (40 mL) and deionized water (90 mL) at room temperature with stirring for 30 minutes. Dopamine hydrochloride (0.5 g) is dissolved in deionized water (10 mL) and added to the solution. After the reaction was carried out for 30 hours, the product was separated, washed with a large amount of deionized water, and dried in a vacuum oven overnight. Heat treatment was performed for 2 hours at 700° C. (ramping rate = 5° C./min) under Ar atmosphere.

[Example of formation of NCB(m)]

NCB(m) is formed from NCB in the same way as NCS(m) is formed from NCS.

Figure 1 shows a TEM (transmission electron microscopy) image of the NCS, Figure 2 shows an AFM (atomic force microscopy) image of the NCS, Figure 3 shows the lines (i), (ii), and (iii) of Figure 2 The profile taken is shown.

1 to 3 , an N-doped carbon sheet (NCS) has a two-dimensional structure having a size of several micrometers and a thickness of less than 10 nm.

4 shows a TEM image of NCS(m), and FIG. 5 shows a TEM image of NCB(m).

4 and 5 , NCS(m) having a micropore structure may be formed by performing heat treatment on the NCS under NH ₃ gas. Moreover, NCB (m) can be formed by heat-processing with respect to NCB under NH ₃ gas. Since the two-dimensional structure is well maintained even after NH ₃ heat treatment for NCS, NCS(m) may also have a two-dimensional structure.

The sizes of NCB and NCB(m) are 375±35nm and 377±38nm, respectively, and there is little change in size. The interlayer distance of NCS(m) is about 0.42 nm, indicating the presence of a partially oxidized carbon structure based on the interlayer distance of graphite (0.32 nm) and graphite oxide (0.6-1.1 nm).

6 shows N ₂ adsorption and desorption isotherms of NCS, NCS (m), NCB, and NCB (m).

Referring to FIG. 6 , according to the N ₂ isotherm analysis, the surface area is greatly increased by the NH ₃ heat treatment. Both NCS(m) and NCB(m) show general type I isothermal properties, showing that the activated surface region has a micropore structure.

7 shows the BET surface area and micropore surface area of NCS(m) and NCB(m). Referring to FIG. 7 , NCB(m) and NCS(m) have similar Brunauer-Emmett-Teller (BET) surface areas and micropore structures.

In addition, although not shown in the drawings, Raman and XRD analysis were performed to understand the change in physicochemical properties after NH ₃ heat treatment. There is no significant change in the ratio of D band (about 1336 cm ^-1 ) to G band (about 1594 cm ^-1 ) (I _D /I _G ) in the Raman spectra of NCS and NCS(m). The X-ray diffraction (XRD) patterns of NCS and NCS(m) show two similar patterns at 24° and 44° corresponding to (002) and (101) reflections of carbon. These XRD and Raman spectroscopy results show that both NCS and NCS(m) have similar carbon structures, which is also confirmed by carbon K edge electron energy loss spectra (EELS). Similar features of the sp ² and sp ³ regions indicate that the sp ² (π ^* ) properties of the carbon structure are not lost, where activation of the surface area is important to ensure sufficient electrical conductivity.

8 shows the N 1s XPS spectra of NCS, NCS(m), NCB, and NCB(m), and FIG. 9 shows the N functional group content of NCS, NCS(m), NCB, and NCB(m). X-ray photoelectron spectroscopy (XPS) analysis was performed to characterize the N functional group, and surface sensitive properties were evaluated using a binding energy of 630 eV from a synchrotron radiation source.

8 and 9, NCS and NCB show similar N 1s properties indicating that they are chemically similar. In the high-resolution XPS N 1s spectrum of NCS(m) after the NH ₃ activation heat treatment process, the content of pyridinic N (398.5 eV) increased while the content of graphite N (401 eV) decreased. The contents of pyrrolic N (400.3 eV) and oxidized N (402.5 eV) did not change. The increase in pyridinic N is due to the transformation of the oxidized species to the pyridinic NC structure in the edge carbon structure during NH ₃ activation heat treatment, which is consistent with the decrease in CO species after NH ₃ heat treatment in the C 1s XPS spectrum.

BET and XPS analysis showed that two-dimensional carbon sheets (NCS and NCS(m)) and zero-dimensional carbon balls (NCB and NCB(m)) showed similar physicochemical properties including surface area, pore structure and nitrogen functionality. These results can provide a well-defined model system that can be used to investigate the dimensional effect on the utilization of micropores.

10 shows the oxygen reduction reaction polarities of NCS, NCS(m), NCB, and NCB(m), and FIG. 11 shows the kinetic current densities of NCS, NCS(m), NCB, and NCB(m). Oxygen Reduction Reaction (ORR) electrocatalytic performance was investigated by a Rotating Disk Electrode (RDE) in 0.1 M KOH electrolyte.

10 and 11 , non-porous NCBs and NCSs with a surface area of less than 100 m ² /g show similar ORR activity. The oxygen reduction reaction activity of NCS(m) and NCB(m) is significantly improved compared to non-porous NCS and NCB. This activity enhancement could be attributed to the increased micropore surface area as other factors remained almost the same. A general relationship between activity and electrochemical surface area can be confirmed in porous NCS(m) and NCB(m) compared to non-porous NCS and NCB. However, the activity enhancing factor (kinetic current density at 0.75 V) of NCS(m)/NCS is 110, much higher than that of NCB(m)/NCB of 30. Despite similar physicochemical properties including surface area and pore size, the remarkably high oxygen reduction activity of NCS(m) is attributed to the structure of the electrocatalyst. That is, since the chemical origin of NCS(m) and NCB(m) is the same as that of dopamine, and the nitrogen content by functional group and elemental analysis by XPS spectrum is similar, the difference in activity can be considered to be due to the structural difference of the catalyst.

12 and 13 show the results of EIS analysis of NCS (m) and NCB (m). 12 shows a frequency versus capacitance graph of NCS(m) and NCB(m), and FIG. 13 shows a Nyquist graph of NCS(m) and NCB(m). EIS measurements were performed under Ar saturation conditions (non-Faraday conditions) to measure the electrochemical double layer capacitance, which is a metric of the electrochemical surface area.

12 and 13, in the low-frequency region of the frequency versus capacitance plot, the capacitance of NCS(m) is almost twice higher than that of NCB(m), indicating that almost half of the surface area of NCB(m) is Indicates that it does not participate in an electrochemical reaction. NCS(m) has a short diffusion path in the thickness direction. This shows that the two-dimensional structure is advantageous for increasing the utilization of the micropore structure.

To evaluate the charge transfer resistance under static conditions, EIS analysis was performed under O ₂ saturation conditions. The semicircle in the Nyquist plot indicates that the charge transfer resistance (R _ct ) of NCB(m) is greater than the charge transfer resistance of NCS(m). For quantitative comparison, the EIS results were analyzed by fitting the data using a general Randle circuit EIS model. The double layer capacitance (C _dl ) agrees well with the capacitance values derived from the frequency versus actual capacitance plot under non-paradigm conditions. R _ct of NCB(m) is almost two times larger than R _ct of NCS(m), indicating a large oxygen reduction reaction overpotential. However, the charge transfer resistance per unit surface area (R _ct × F, the resistance normalized to the capacitance, which is the same dimension as the surface area according to the definition of capacitance) is similar. The activity of NCS(m) in terms of kinetic current density is about 4 times higher than that of NCB(m). Based on the fact that the EIS condition is static, the actual electrochemically active surface area of NCS(m) during oxygen reduction reaction measurement is much higher than that of NCB(m), so it is important to improve pore utilization through morphological control in dynamic processes.

Cyclic voltammograms (CVs) were compared under Ar conditions to compare electrochemically active surfaces that can be used for oxygen reduction reactions. According to the area measured by CV, the electrochemical double-layer capacitance of NCS(m) is about 4 times higher, which correlates well with the actual activity difference between NCS(m) and NCB(m). Both non _- Faraday (Ar saturated) and Faraday (O2 saturated) EIS measurements combined with CV analysis showed that the electrochemically active surface area, a major factor in oxygen reduction reaction activity, does not depend on the physical BET surface area but on the actual utilization of micropores. indicates. Therefore, the two-dimensional carbon structure is very advantageous for increasing the utilization of micropores as electrochemically active regions.

14 shows a TEM image of Fe-NCS(m), and FIG. 15 shows an AC-STEM image of Fe-NCS(m). In FIG. 15 , white arrows indicate monoatomic Fe.

Referring to FIG. 14 , Fe-NCS(m) may be used as an electrocatalyst having high oxygen reduction reaction activity by introducing Fe species into NCS(m) having a two-dimensional structure. The Fe-N-C structure included in Fe-NCS(m) exhibits significantly higher oxygen reduction reaction activity, and the M-N-C structure included in M-NCS(m) (M represents a transition metal) is the oxygen reduction reaction activity. function as a site. The XRD results show that Fe-NCS(m) does not show Fe including a crystalline phase and has a typical amorphous carbon structure.

Referring to FIG. 15 , Fe-NCS(m) shows little structural difference compared to NCS(m), but bright spots in FIG. 15 can be identified by aberration-corrected scanning transmission electron microscopy (AC-STEM), and carbon It clearly shows the characteristics of the atoms Fe contained in the sheet.

16 shows the CCWT analysis results of Fe-NCS(m), Fe-Phen, Fe3O4, and Fe EXAFS of Fe metal foil. .

16, in the continuous Cauchy wave transform (CCWT) plot of Fe-NCS(m), Fe-phen(Fe-phenanthroline) and Fe-based reference materials (Fe ₃ O ₄ and Fe metal foil) Fe-NCS ( Fe in m) exists as a single atomic property and is only coordinated with N(O), a characteristic characteristic of Fe-NC moieties. The oxidation state induced at the X-ray absorption near edge structure (XANES) edge position is averaged at 2.3 in the reduced state compared to the precursor, which is related to the Fe oxidation state of FeN ₄ in the carbon matrix being between 2+ and 3+ do.

17 shows the oxygen reduction reaction polarity curves of NCS(m), Fe-NCS(m), and Pt/C.

Referring to FIG. 17 , Fe-NCS(m) exhibits very high oxygen reduction reaction activity with excellent half-wave potential (0.89 vs. RHE) and high reaction selectivity (n = 3.98), which is close to four electron pathways. The addition of 10 mM KCN to the electrolyte significantly decreased the activity of Fe-NCS(m), indicating that Fe-N is the main active site.

18 shows the durability test results of Fe-NCS(m) and Pt/C, and FIG. 19 shows half-wave potentials of Fe-NCS(m) and Pt/C before and after 20,000 cycles. To evaluate the durability of the catalyst, Fe-NCS(m) and Pt/C were cycled in an O ₂ saturated environment between 0.6 and 1.0V.

18 and 19, after the same number of cycles (20,000 cycles), Fe-NCS(m) shows little loss of activity, unlike Pt/C. The half-wave potential of Pt/C decreased from 0.87V to 0.825V, but Fe-NCS(m) did not show a difference, and thus had excellent electrochemical stability.

To confirm the applicability of Fe-NCS(m) to actual devices, Fe-NCS(m) was used as a cathode catalyst in an anion exchange membrane fuel cell (AEMFC). The open circuit voltage and current density at 0.6V were 1.025V and 438mA/cm ² . The maximum power density of 279 mW/cm ² is high considering the low catalyst loading compared to other carbon-based catalysts. This indicates that practical applications are possible.

So far, specific embodiments of the present invention have been described. Those of ordinary skill in the art to which the present invention pertains will understand that the present invention may be implemented in a modified form without departing from the essential characteristics of the present invention. Therefore, the disclosed embodiments are to be considered in an illustrative rather than a restrictive sense. The scope of the present invention is indicated in the claims rather than the foregoing description, and all differences within the scope equivalent thereto should be construed as being included in the present invention.

Claims (20)

A carbon sheet having micropores and containing nitrogen (N),
The carbon sheet,
forming a precursor solution comprising a carbon precursor comprising nitrogen;
providing a template to the precursor solution and then drying the precursor solution to form a template-carbon complex;
forming a first carbon sheet by performing a first heat treatment on the template-carbon composite; and
A carbon sheet formed by a method comprising the step of performing a second heat treatment on the first carbon sheet to form a second carbon sheet having micropores. The method of claim 1,
The carbon precursor is a carbon sheet, characterized in that it comprises dopamine. The method of claim 1,
The template is a carbon sheet, characterized in that it contains salt (NaCl). 4. The method of claim 3,
Further comprising the step of removing the template after the first heat treatment,
The carbon sheet, characterized in that the template is removed by dissolving with water. The method of claim 1,
The first heat treatment is performed under an inert gas at a first temperature,
The second heat treatment is a carbon sheet, characterized in that performed under NH ₃ gas or CO ₂ gas at a second temperature higher than the first temperature. The method of claim 1,
The carbon sheet, characterized in that the first carbon sheet and the second carbon sheet have a two-dimensional structure. forming a precursor solution comprising a carbon precursor comprising nitrogen;
providing a template to the precursor solution and then drying the precursor solution to form a template-carbon complex;
forming a first carbon sheet by performing a first heat treatment on the template-carbon composite; and
and performing a second heat treatment on the first carbon sheet to form a second carbon sheet having micropores. 8. The method of claim 7,
The carbon precursor is a method of forming a carbon sheet, characterized in that it comprises dopamine. 8. The method of claim 7,
The template is a method of forming a carbon sheet, characterized in that it contains salt (NaCl). 10. The method of claim 9,
Further comprising the step of removing the template after the first heat treatment,
The method for forming a carbon sheet, characterized in that the template is removed by dissolving with water. 8. The method of claim 7,
The first heat treatment is performed under an inert gas at a first temperature,
The second heat treatment is a method of forming a carbon sheet, characterized in that performed under NH ₃ gas or CO ₂ gas at a second temperature higher than the first temperature. 8. The method of claim 7,
The method of forming a carbon sheet, characterized in that the first carbon sheet and the second carbon sheet have a two-dimensional structure. As a porous catalyst having micropores, containing nitrogen (N), and supporting a metal,
The porous catalyst is
forming a precursor solution including a carbon precursor including nitrogen and a metal precursor;
providing a template to the precursor solution and then drying the precursor solution to form a template-metal-carbon complex;
performing a first heat treatment on the template-metal-carbon composite to form a first carbon sheet supporting the metal; and
A porous catalyst formed by a method comprising the step of performing a second heat treatment on the first carbon sheet to form a second carbon sheet having micropores and supporting the metal. 14. The method of claim 13,
The carbon precursor is a porous catalyst comprising dopamine. 14. The method of claim 13,
The metal precursor is a porous catalyst comprising a transition metal. 14. The method of claim 13,
The porous catalyst is a porous catalyst, characterized in that it comprises an MNC structure (M represents a transition metal). 14. The method of claim 13,
The template is a porous catalyst comprising salt (NaCl). 18. The method of claim 17,
Further comprising the step of removing the template after the first heat treatment,
The template is a porous catalyst, characterized in that removed by dissolving in water. 14. The method of claim 13,
The first heat treatment is performed under an inert gas at a first temperature,
The second heat treatment is a porous catalyst, characterized in that performed under NH ₃ gas or CO ₂ gas at a second temperature higher than the first temperature. 14. The method of claim 13,
The porous catalyst, characterized in that the first carbon sheet and the second carbon sheet have a two-dimensional structure.

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